Hinge assemblies for a domestic refrigerator

ABSTRACT

A domestic appliance includes a cabinet with a door positioned at a front of the cabinet, a closer assembly secured to the door, a mounting bracket coupled to the front of the cabinet, a hinge pin extending upwardly from the mounting bracket, and a coupler body. The closer assembly includes a downwardly-extending shaft. The coupler body has a first inner sidewall defining a lower aperture that receives an upper end of the hinge pin, and a second inner sidewall defining an upper aperture that receives a lower end of the shaft. The shaft of the closer assembly has a first plurality of splines formed thereon, and the second inner sidewall of the coupler body has a second plurality of splines formed thereon. The second plurality of splines of the coupler body engages the first plurality of splines of the shaft.

This application claims priority under 35 U.S.C. §120 to U.S. patentapplication Ser. No. 13/428,031 entitled “HINGE ASSEMBLY FOR A DOMESTICREFIGERATOR,” by Daryl Reuter et al., which was filed on Mar. 23, 2012,and U.S. Utility patent application Ser. No. 13/428,067 entitled“ADJUSTABLE HINGE ASSEMBLY FOR A DOMESTIC REFIGERATOR,” which was filedby Julie Mann et al. which was filed on Mar. 23, 2012, both of which areassigned to the same assignee and which are hereby incorporated byreference.

TECHNICAL FIELD

The present disclosure relates generally to a domestic refrigerator andmore particularly to a hinge assembly for a door of a domesticrefrigerator.

BACKGROUND

A domestic refrigerator is a device used to store food items in a homeat preset temperatures. A domestic refrigerator typically includes oneor more temperature-controlled compartments into which food items may beplaced to preserve the food items for later consumption. A domesticrefrigerator also typically includes a door that permits user access tothe temperature-controlled compartment defined in the refrigeratorcabinet. The door may be mounted to the cabinet via a hinge assembly.

SUMMARY

According to one aspect of the disclosure, a domestic refrigerator isdisclosed. The domestic refrigerator includes a cabinet having atemperature-controlled compartment defined therein, and a doorpositioned at a front of the cabinet. The door is operable to pivotabout an axis of rotation between a closed position in which user accessto the temperature-controlled compartment is prevented and an openposition in which user access to the temperature-controlled compartmentis permitted. The domestic refrigerator also includes a cam platecoupled to the door, and the cam plate includes a first cam surface. Thedomestic refrigerator has a coupler body including a second cam surfaceengaged with the first cam surface, a lower surface having an openingdefined therein, and an inner wall extending upwardly from the openingto define an aperture in the coupler body. A hinge pin defines the axisof rotation and includes a cylindrical shaft having an upper endpositioned in the aperture of the coupler body and a plurality oflongitudinal slots defined in the cylindrical shaft. A plurality ofsplines extend inwardly from the inner wall of the coupler body, andeach spline is received in a corresponding longitudinal slot of thehinge pin to prevent rotation of the coupler body about the axis ofrotation.

In some embodiments, the domestic refrigerator may further include anadjustment mechanism configured to move the door vertically relative tothe cabinet between a first position and a second position. In someembodiments, the cylindrical shaft of the hinge pin may have apassageway defined therein, and the adjustment mechanism may include athreaded rod positioned in the passageway of the cylindrical shaft. Thethreaded rod may have an upper end engaged with the coupler body.

In some embodiments, the inner wall of the coupler body may extendupwardly from the opening to an inner surface, and the coupler body mayinclude a central shaft that extends downwardly from the inner surface.The central shaft may have a lower end positioned in the passageway ofthe cylindrical shaft and engaged with the upper end of the threadedrod.

Additionally, in some embodiments, the threaded rod may have a pluralityof outer threads, and the cylindrical shaft of the hinge pin may includean inner wall that defines the passageway therethrough. The inner wallof the cylindrical shaft may have a plurality of inner threads definedtherein that are engaged with the outer threads of the threaded rod suchthat rotation of the threaded rod in a first direction may cause upwardmovement of the coupler body and the door, and rotation of the threadedrod in a second direction may cause downward movement of the couplerbody and the door.

In some embodiments, the adjustment mechanism may include a stopconfigured to prevent upward movement of the threaded rod beyond apredetermined position corresponding to the second position of the door.In some embodiments, the stop may include a substantially smooth sectionof the inner wall of the cylindrical shaft. The substantially smoothsection may be positioned above the plurality of inner threads. In someembodiments, a distance may be defined between the first position andthe second position of the door. The distance may be approximately threemillimeters.

In some embodiments, the domestic refrigerator may further include abushing has the cam plate. The door may include a frame and a frontpanel secured to the frame, and the bushing may be coupled to the frameand positioned behind the front panel. Additionally, in someembodiments, the bushing may include a bottom surface having an openingdefined therein, an inner wall extending upwardly from the opening to aninner surface including the first cam surface, and an aperture definedby the inner wall and the inner surface. The coupler body may have anupper end positioned in the aperture of the bushing. In someembodiments, the plurality of splines may include six splines extendingfrom the inner wall of the coupler body.

According to another aspect, a domestic refrigerator includes a cabinethaving a temperature-controlled compartment defined therein, and a dooroperable to pivot about an axis of rotation between a closed position inwhich user access to the temperature-controlled compartment is preventedand an open position in which user access to the temperature-controlledcompartment is permitted. The domestic refrigerator also includes ahinge assembly including a hinge pin defining the axis of rotation andan adjustment mechanism configured to move the door vertically between afirst position and a second position. The adjustment mechanism includesa threaded rod positioned in a passageway defined in the hinge pin, anda stop positioned in the passageway defined in the hinge pin. Thethreaded rod is configured to rotate in a first direction to causeupward movement of the door and a second direction to cause downwardmovement of the door. The stop is configured to prevent upward movementof the threaded rod beyond a predetermined position corresponding to thesecond position of the door.

In some embodiments, the hinge assembly may include a bushing secured tothe door, and a coupler body coupled to the hinge pin. The bushing mayinclude a first cam surface, and the coupler body may include a secondcam surface engaged with the first cam surface. In some embodiments, thecoupler body may include a lower surface positioned opposite the secondcam surface. The lower surface may have an opening defined therein andan inner wall extending upwardly from the opening to an inner surface.The inner wall and the inner surface may define an aperture in thecoupler body, and an upper end of the hinge pin may be positioned in theaperture defined in the coupler body.

Additionally, in some embodiments, the coupler body may include acentral shaft that extends downwardly from the inner surface. Thecentral shaft may have a lower end positioned in the passageway of thehinge pin and engaged with an upper end of the threaded rod. In someembodiments, the hinge pin may include a longitudinal slot defined in anouter surface thereof, and the coupler body may include a splineextending from the inner wall thereof. The spline may be received in thelongitudinal slot of the hinge pin.

In some embodiments, the longitudinal slot may include at least sixlongitudinal slots, and the spline may include at least six splinesextending from the inner wall of the coupler body. Each of the splinesmay be received in a corresponding longitudinal slot of the hinge pin.

In some embodiments, the domestic refrigerator may further include afirst bracket secured to the door, and the first bracket may include afirst flange coupled to the door and a second flange extendingdownwardly from the first flange. The domestic refrigerator may alsoinclude a second bracket including a mounting plate having the hinge pinsecured thereto, and a side wall extending upwardly from an uppersurface of the mounting plate. The second flange may be engaged with theside wall of the second bracket when the door is in the open position.

According to another aspect, a domestic refrigerator includes a cabinethaving a temperature-controlled compartment defined therein, a pair ofdoors positioned at a front of the cabinet, and a pair of cam plates.Each cam plate is secured to one of the pair of doors and includes alower cam surface. The domestic refrigerator also includes a pair ofcoupler bodies, and each coupler body has an upper cam surfaceconfigured to engage with the lower cam surface of one of the pair ofdoors, and an aperture defined therein. The domestic refrigeratorincludes a first hinge pin and a second hinge pin. The first hinge pinhas a plurality of longitudinal slots defined in an outer surfacethereof, and an upper end positioned in a first coupler body of the pairof coupler bodies. The second hinge pin has a plurality of longitudinalslots defined in an outer surface thereof, and an upper end positionedin a second coupler body of the pair of coupler bodies. The firstcoupler body includes a plurality of splines that are received in theplurality of longitudinal slots of the first hinge pin, and the secondcoupler body includes a plurality of splines that are received in theplurality of longitudinal slots of the second hinge pin.

In some embodiments, the domestic refrigerator may further include athreaded rod engaged with the first coupler body. The first hinge pinmay have an inner wall extending between an upper opening and a loweropening to define a passageway therethrough. The inner wall may have aplurality of threads defined therein engaged with the threaded rod suchthat rotation of the threaded rod in a first direction may cause upwardmovement of the coupler body and a first door of the pair of doors, androtation of the threaded rod in a second direction may cause downwardmovement of the coupler body and the first door. The second hinge pinmay have a substantially smooth inner wall extending between an upperopening and a lower opening to define a passageway therethrough.

According to another aspect, the domestic refrigerator includes acabinet having a temperature-controlled compartment defined therein, anda door operable to pivot about an axis of rotation between a closedposition in which user access to the temperature-controlled compartmentis prevented and an open position in which user access to thetemperature-controlled compartment is permitted. The domesticrefrigerator also includes a cam plate coupled to the door that includesa first cam surface, and a coupler body having a second cam surfaceengaged with the first cam surface, a lower surface positioned oppositethe second cam surface, the lower surface having an opening definedtherein, and an inner wall extending upwardly from the opening to definean aperture in the coupler body. A hinge pin defines the axis ofrotation. The hinge pin has an upper end positioned in the aperture ofthe coupler body, and the upper end includes a pair of substantiallyplanar surfaces and a pair of convex surfaces connecting the pair ofsubstantially planar surfaces. The inner wall of the coupler body has apair of substantially planar surfaces engaged with the pair ofsubstantially planar surfaces of the hinge pin to prevent rotation ofthe coupler body about the axis of rotation.

In some embodiments, the hinge pin may have a passageway definedtherein, the inner wall of the coupler body may extend upwardly from theopening to an inner surface, and the coupler body may include a centralshaft that extends downwardly from the inner surface. The central shaftmay have a lower end positioned in the passageway of the hinge pin. Insome embodiments, the domestic refrigerator may further include anadjustment mechanism configured to move the door vertically between afirst position and a second position relative to the cabinet.

Additionally, in some embodiments, the adjustment mechanism may includea threaded rod positioned in the passageway of the hinge pin. Thethreaded rod may have an upper end engaged with the lower end of thecentral shaft of the coupler body. In some embodiments, the threaded rodmay have a plurality of outer threads, and the hinge pin may include aninner wall that defines the passageway therethrough. The inner wall mayhave a plurality of inner threads defined therein that are engaged withthe outer threads of the threaded rod such that rotation of the threadedrod in a first direction may cause upward movement of the coupler bodyand the door, and rotation of the threaded rod in a second direction maycause downward movement of the coupler body and the door.

According to another aspect, the domestic refrigerator includes a dooroperable to pivot about an axis of rotation, a cam plate coupled to thedoor that includes a first cam surface, and a coupler body. The couplerbody has a second cam surface engaged with the first cam surface, alower surface having an opening defined therein, and an inner wallextending upwardly from the opening to define an aperture in the couplerbody. The inner wall includes a pair of substantially planar surfaces. Ahinge pin defines the axis of rotation. The hinge pin has an upper endpositioned in the aperture of the coupler body. The upper end includes apair of substantially planar surfaces engaged with the pair ofsubstantially planar surfaces of the coupler body to prevent rotation ofthe coupler body about the axis of rotation. The domestic refrigeratoralso includes a threaded rod positioned in a passageway defined in thehinge pin and engaged with the coupler body. The threaded rod isconfigured to rotate in a first direction to cause upward movement ofthe door and a second direction to cause downward movement of the door.

In some embodiments, the inner wall of the coupler body may extendupwardly from the opening to an inner surface. The inner wall and theinner surface may define the aperture in the coupler body, and thecoupler body may include a central shaft that extends downwardly fromthe inner surface. The central shaft may have a lower end positioned inthe passageway of the hinge pin and engaged with an upper end of thethreaded rod.

In some embodiments, the domestic refrigerator may include a stoppositioned in the passageway defined in the hinge pin. The stop may beconfigured to prevent upward movement of the threaded rod beyond apredetermined position.

In some embodiments, the upper end of the hinge pin may include a pairof convex surfaces that connect the pair of substantially planarsurfaces of the hinge pin, and the coupler body may include a pluralityof ribs extending inwardly from the inner wall. The plurality of ribsmay bee engaged with the pair of convex surfaces of the hinge pin.

In some embodiments, the domestic refrigerator may include a bushingsecured to the door. The bushing may include a bottom surface having anopening defined therein, an inner wall extending upwardly from theopening to an inner surface that includes the first cam surface, and theaperture may be defined by the inner wall and the inner surface. Thecoupler body may have an upper end positioned in the aperture of thebushing. The upper end of the coupler body may include the second camsurface.

According to another aspect, a domestic refrigerator includes a cabinethaving a temperature-controlled compartment defined therein, and a dooroperable to pivot about an axis of rotation between a closed position inwhich user access to the temperature-controlled compartment is preventedand an open position in which user access to the temperature-controlledcompartment is permitted. The domestic refrigerator also includes abushing secured to the door and a coupler body. The bushing has anaperture defined therein, and a first cam surface positioned in theaperture. The coupler body has an upper end positioned in the apertureof the bushing, and the upper end includes a second cam surface engagedwith the first cam surface. The coupler body also has a lower surfacehaving an opening defined therein, and an inner wall extending upwardlyfrom the opening to define an aperture in the coupler body. The innerwall includes a pair of substantially planar surfaces. A hinge pindefines the axis of rotation. The hinge pin has an upper end positionedin the aperture of the coupler body, the upper end including a pair ofsubstantially planar surfaces engaged with the pair of substantiallyplanar surfaces of the coupler body to prevent rotation of the couplerbody about the axis of rotation.

In some embodiments, the inner wall of the coupler body may extendupwardly from the opening to an inner surface. The inner wall and theinner surface may define the aperture in the coupler body, and thecoupler body may include a central shaft that extends downwardly fromthe inner surface. The central shaft may have a lower end positioned ina passageway defined in the hinge pin.

In some embodiments, the domestic refrigerator may further include anadjustment mechanism configured to move the door vertically between afirst position and a second position relative to the cabinet.Additionally, in some embodiments, the domestic refrigerator may includea threaded rod positioned in the passageway defined in the hinge pin andengaged with the lower end of the coupler body. The threaded rod may beconfigured to rotate in a first direction to cause upward movement ofthe door and a second direction to cause downward movement of the door.

According to another aspect, a domestic refrigerator includes a cabinethaving a temperature-controlled compartment defined therein and a doorpositioned at a front of the cabinet. The door is operable to pivotabout an axis of rotation between a closed position in which user accessto the temperature-controlled compartment is limited and an openposition in which user access to the temperature-controlled compartmentis permitted. The domestic refrigerator also includes a closer assemblyincluding a base secured to the door and a downwardly-extending shaftmoveably coupled to the base, a mounting bracket coupled to the front ofthe cabinet, a hinge pin defining the axis of rotation and extendingupwardly from the mounting bracket, and a coupler body. The coupler bodyhas a first inner sidewall that defines a lower aperture that receivesan upper end of the hinge pin, and a second inner sidewall that definesan upper aperture that receives a lower end of the shaft. The shaft ofthe closer assembly has a first plurality of splines formed thereon, andthe second inner sidewall of the coupler body has a second plurality ofsplines formed thereon. The second plurality of splines of the couplerbody engages the first plurality of splines of the shaft to preventrelative axial rotation between the coupler body and the shaft.

In some embodiments, the coupler body may have a third plurality ofsplines that extend inwardly from the first inner sidewall. The hingepin may include a shaft having an upper end positioned in the loweraperture of the coupler body, and a plurality of longitudinal slotsdefined in the shaft. Each spline of the third plurality of splines maybe received in a corresponding longitudinal slot of the hinge pin toprevent rotation of the coupler body about the axis of rotation.

In some embodiments, the domestic refrigerator may further include anadjustment mechanism configured to move the door vertically relative tothe cabinet between a first position and a second position. In someembodiments, the hinge pin may have a passageway defined therein, andthe adjustment mechanism may include a threaded rod positioned in thepassageway of the shaft. The threaded rod may have an upper end engagedwith the coupler body.

In some embodiments, the coupler body may include a central shaftpositioned in the lower aperture. The central shaft may have a lower endthat is positioned in the passageway of the shaft and engaged with theupper end of the threaded rod.

In some embodiments, the threaded rod may have a plurality of outerthreads, and the hinge pin may include an inner wall that defines thepassageway therethrough. The inner wall of the hinge pin may have aplurality of inner threads defined therein that are engaged with theouter threads of the threaded rod such that rotation of the threaded rodin a first direction causes upward movement of the coupler body and thedoor, and rotation of the threaded rod in a second direction causesdownward movement of the coupler body and the door.

In some embodiments, the adjustment mechanism may include a stopconfigured to prevent upward movement of the threaded rod beyond apredetermined position corresponding to the second position of the door.In some embodiments, the stop may include a substantially smooth sectionof the inner wall of the hinge pin. The substantially smooth section maybe positioned above the plurality of inner threads.

In some embodiments, the closer assembly may include a biasing elementhaving a first end coupled to the shaft and a second end coupled to thebase. The biasing element may be configured to inhibit movement of thedoor about the axis of rotation. Additionally, in some embodiments, thefirst plurality of splines may include six splines.

According to another aspect, a domestic refrigerator includes a cabinethaving a temperature-controlled compartment defined therein, and a dooroperable to pivot about an axis of rotation to an open position in whichuser access to the temperature-controlled compartment is permitted. Thedomestic refrigerator further includes a closer assembly, and the closerassembly includes a base secured to the door and a downwardly-extendingshaft moveably coupled to the base. The domestic refrigerator alsoincludes a hinge assembly, having a hinge pin defining the axis ofrotation and an adjustment mechanism configured to move the doorvertically between a first position and a second position. Theadjustment mechanism of the hinge assembly includes a coupler bodypositioned over the hinge pin, a threaded rod positioned in a passagewaydefined in the hinge pin, and a stop positioned in the passagewaydefined in the hinge pin. The coupler body includes an inner side wallthat defines an aperture receiving the shaft of the closer assembly. Thethreaded rod is configured to rotate in a first direction to causeupward movement of the door and a second direction to cause downwardmovement of the door. The stop is configured to prevent upward movementof the threaded rod beyond a predetermined position corresponding to thesecond position of the door.

In some embodiments, the coupler body may include a central shaft havinga lower end that is positioned in the passageway of the hinge pin and isengaged with an upper end of the threaded rod. In some embodiments, thehinge pin may include a longitudinal slot defined in an outer surfacethereof, and the coupler body may include a spline extending from aninner wall thereof. The spline may be received in the longitudinal slotof the hinge pin.

In some embodiments, the shaft of the closer assembly may have a splineformed thereon, and the coupler body may have a second spline formedthereon. The spline of the shaft may engage the second spline of thecoupler body to prevent relative axial rotation between the coupler bodyand the shaft.

In some embodiments, the closer assembly may include a biasing elementhaving a first end coupled to the shaft and a second end coupled to thebase. The biasing element may be configured to inhibit movement of thedoor about the axis of rotation. Additionally, in some embodiments, thebiasing element may include a coil spring.

In some embodiments, the shaft of the closer assembly may include anupper surface having the spline formed thereon and a lower surface thatis substantially smooth. In some embodiments, the longitudinal slot mayinclude at least six longitudinal slots, and the spline may include atleast six splines extending from the inner wall of the coupler body.Each of the splines may be received in a corresponding longitudinal slotof the hinge pin.

According to another aspect of the disclosure, a domestic applianceincludes a cabinet with a door positioned at a front of the cabinet, acloser assembly secured to the door, a mounting bracket coupled to thefront of the cabinet, a hinge pin extending upwardly from the mountingbracket, and a coupler body. The closer assembly includes adownwardly-extending shaft. The coupler body has a first inner sidewalldefining a lower aperture that receives an upper end of the hinge pin,and a second inner sidewall defining an upper aperture that receives alower end of the shaft. The shaft of the closer assembly has a firstplurality of splines formed thereon, and the second inner sidewall ofthe coupler body has a second plurality of splines formed thereon. Thesecond plurality of splines of the coupler body engages the firstplurality of splines of the shaft.

In some embodiments, the hinge pin may include a shaft having an upperend positioned in the lower aperture of the coupler body, and aplurality of longitudinal slots defined in the shaft. The coupler bodymay have a third plurality of splines that extend inwardly from an innerwall. Each spline of the third plurality of splines may be received in acorresponding longitudinal slot of the hinge pin.

BRIEF DESCRIPTION OF THE DRAWINGS

The detailed description particularly refers to the following figures,in which:

FIG. 1 is a front elevation view of a domestic refrigerator;

FIG. 2 is an exploded, cross-sectional view of a right-hand door and oneembodiment of an adjustable hinge assembly of the refrigerator of FIG.1;

FIG. 3 is a rear perspective view of the adjustable hinge assembly ofFIG. 2;

FIG. 4 is a perspective view of a hinge pin of the adjustable hingeassembly of FIG. 2;

FIG. 5 is a bottom perspective view of a coupler body of the adjustablehinge assembly of FIG. 2;

FIG. 6 is a cross-sectional side elevation view of the refrigerator ofFIG. 1 showing the right-hand door in one vertical position relative tothe refrigerator cabinet;

FIG. 7 is a view similar to FIG. 6 showing the right-hand door inanother vertical position relative to the refrigerator cabinet;

FIG. 8 is a cross-sectional top plan view of the refrigerator of FIG. 1with adjustable hinge assembly of FIG. 2;

FIG. 9 is an exploded, cross-sectional view of the left-hand door andone embodiment of a fixed hinge assembly of the refrigerator of FIG. 1;

FIG. 10 is a cross-sectional side elevation view of the refrigerator ofFIG. 1 showing the left-hand door in one vertical position relative tothe refrigerator cabinet;

FIG. 11 is an exploded, cross-sectional view of a right-hand door andanother embodiment of an adjustable hinge assembly of the refrigeratorof FIG. 1;

FIG. 12 is a perspective view of a hinge pin of the adjustable hingeassembly of FIG. 11;

FIG. 13 is a bottom perspective view of a coupler body of the adjustablehinge assembly of FIG. 11;

FIG. 14 is a cross-sectional top plan view of the refrigerator of FIG. 1with adjustable hinge assembly of FIG. 11;

FIG. 15 is an exploded, cross-sectional view of a right-hand door andone embodiment of an adjustable hinge assembly of the refrigerator ofFIG. 1;

FIG. 16 is a perspective view of a spline shaft, a coupler body, and ahinge pin of the adjustable hinge assembly of FIG. 15;

FIG. 17 is a bottom perspective view of the coupler body of FIG. 16;

FIG. 18 is a cross-sectional side elevation view of the adjustable hingeassembly of FIG. 15 showing the right-hand door in one verticalposition;

FIG. 19 is a view similar to FIG. 18 showing the right-hand door inanother vertical position; and

FIG. 20 is a cross-sectional top plan view of the refrigerator of FIG. 1with adjustable hinge assembly of FIG. 15.

DETAILED DESCRIPTION OF THE DRAWINGS

While the concepts of the present disclosure are susceptible to variousmodifications and alternative forms, specific exemplary embodimentsthereof have been shown by way of example in the drawings and willherein be described in detail. It should be understood, however, thatthere is no intent to limit the concepts of the present disclosure tothe particular forms disclosed, but on the contrary, the intention is tocover all modifications, equivalents, and alternatives falling withinthe spirit and scope of the invention as defined by the appended claims.

Referring to FIG. 1, a home appliance is shown as a domesticrefrigerator appliance 10 (hereinafter refrigerator 10). Therefrigerator 10 includes a cabinet 12 and a lower frame 14 that supportsthe cabinet 12. The refrigerator cabinet 12 defines atemperature-controlled, refrigerated compartment 16 into which a usermay place and store food items such as milk, cheese, produce, etcetera.The refrigerated compartment 16 is operable to maintain stored fooditems at a predefined temperature.

As shown in FIG. 1, the refrigerator cabinet 12 defines atemperature-controlled freezer compartment 18, which is also operable tomaintain food items stored therein at a certain temperature. Therefrigerator 10 includes a drawer 20 that permits user access to thefreezer compartment 18 such that food items may be placed in andretrieved from shelves and drawers positioned therein. When the drawer20 is in the closed position shown in FIG. 1, user access to the freezercompartment 18 is prevented. A handle 22 is located on the drawer 20,and the user may use the handle 22 to pull the drawer 20 open. It willbe appreciated that in other embodiments the freezer compartment may bepositioned above or side-by-side with the refrigerated compartment 16,either as a free standing refrigerator or a built-in refrigerator. Itwill be further appreciated that in other embodiments the refrigerator10 may not have a freezer compartment.

The refrigerator 10 includes a right-hand door 24 and a left-hand door26 that permit user access to the refrigerated compartment 16 such thatfood items may be placed in and retrieved from the refrigerator 10. Theright-hand door 24 is hinged to the front of the refrigerator cabinet 12via an upper hinge assembly 28 and a lower hinge assembly 30. A handle32 is located on a front panel 34 of the door 24, and the user may usethe handle 32 to pull the right-hand door 24 open. The left-hand door 26is hinged to the front of the refrigerator cabinet 12 via another upperhinge assembly 28 and a lower hinge assembly 36. Another handle 32 islocated on a front panel 38 of the door 26, and the user may use thathandle 32 to pull the left-hand door 26 open. As described in greaterdetail below, the lower hinge assembly 30 of the right-hand door 24 isoperable to adjust the closed vertical position of the door 24 relativeto the refrigerator cabinet 12. In the illustrative embodiment, thelower hinge assembly 36 of the left-hand door 26 is not adjustable andthe closed vertical position of the door 26 is fixed.

Referring now to FIG. 2, the lower hinge assembly 30 of the right-handdoor 24 is configured to be secured to a hinge bracket 40. The hingebracket 40 is formed from a metallic material, such as, for example,steel, and is sized to support the weight of the right-hand door 24. Thehinge bracket 40 includes a vertical flange 42 and a mounting plate 48that extends horizontally from the flange 42. The vertical flange 42 isconfigured to be attached to a front wall 44 of the cabinet 12 via aplurality of bolts (not shown), which extend through holes 46 formed inthe flange 42 to engage the cabinet 12.

The mounting plate 48 of the hinge bracket 40 extends outwardly from thecabinet 12 when the bracket 40 is secured to the cabinet 12. Themounting plate 48 has an upper surface 50 and a lower surface 52positioned opposite the upper surface 50. An opening 54 is defined inthe upper surface 50 of the mounting plate 48, and an inner wall 56extends downwardly from the opening 54 to define a bore 58 through themounting plate 48. In the illustrative embodiment, the opening 54 iscircular, and the bore 58 is substantially cylindrical. It should beappreciated that in other embodiments the opening may be oblong, square,or other geometric shapes.

As shown in FIG. 3, the mounting plate 48 includes a side wall 60 thatextends between the surfaces 50, 52. The side wall 60 defines a pocket62 positioned adjacent to the lower hinge assembly 30. The mountingplate 48 also includes a flange 64 that extends upwardly from the uppersurface 50. The flange 64 has a side wall 66 that is aligned with sidewall 60, and the walls 60, 66 cooperate to act as a stop for theright-hand door 24, as described in greater detail below.

The lower hinge assembly 30 of the right-hand door 24 includes a hingepin 68 configured to be secured to the hinge bracket 40, a bushing 70configured to be secured to the right-hand door 24, and a coupler body72 positioned between the hinge pin 68 and the bushing 70. As shown inFIG. 4, the hinge pin 68 has a body 74 and a circular flange 76 thatextends outwardly from the body 74. The body 74 has a tail 78 thatextends downwardly from the circular flange 76 to a lower end 80. Thetail 78 has a cross-sectional geometry that is shaped to match the bore58 of the mounting plate 48. In the illustrative embodiment, the tail 78is cylindrical and has an outer diameter that is sized such that thetail 78 may be received in the bore 58.

The body 74 of the hinge pin 68 includes a cylindrical shaft 82, whichextends upwardly from the circular flange 76 to an upper end 84. Theshaft 82 defines a vertically-extending longitudinal axis 86 of thehinge pin 68. As described in greater detail below, the right-hand door24 is configured to pivot about the axis 86 to move between the closedposition and the open position when the hinge assembly 30 and the door24 are assembled. The shaft 82 of the pin body 74 has an outer surface88 and a plurality of grooves or slots 90 defined in the outer surface88. As shown in FIG. 4, each slot 90 has an opening 92 defined in theupper end 84 of the body 74. A concave surface 94 extends downwardlyfrom each opening 92 and inwardly from the outer surface 88 to defineeach slot 90. The slots 90 extend parallel to the axis 86 and are spacedapart equally from one another around the outer circumference of thecylindrical shaft 82. In the illustrative embodiment, the hinge pin 68includes six slots 90, but it should be appreciated that in otherembodiments the hinge pin 68 may include additional or fewer slots.

Returning to FIG. 2, the body 74 of the hinge pin 68 has an opening 96defined in the upper end 84 and another opening 98 defined in the lowerend 80. An inner wall 100 extends between the openings 96, 98 to definea cylindrical passageway 102 through the hinge pin 68. The inner wall100 of the body 74 includes a lower surface 104 having a number ofinternal threads 106 defined therein and an upper surface 108 positionedabove the lower surface 104. The upper surface 108 of the inner wall 100is substantially smooth.

In the illustrative embodiment, the hinge pin 68 is formed as a singlemonolithic component from a metallic material, such as, for example,cold-formed steel. In other embodiments, the body 74 and the circularflange 76 may be formed as separate components that are assembled. Itshould be appreciated that the configuration of one or more of thosecomponents of the hinge pin 68 may be modified in other embodiments. Itshould further be appreciated that in other embodiments one or more ofthe components may be made from a polymeric material, such as, forexample, a rigid plastic.

As described above, the lower hinge assembly 30 also includes a couplerbody 72 that is configured to be engaged with the hinge pin 68. Thecoupler body 72 includes an outer shell 114 formed from a polymericmaterial, such as, for example, nylon. It should be appreciated that inother embodiments the outer shell 114 may be formed from a metallicmaterial, such as, for example, cold-rolled steel. The outer shell 114has a flange 116 that extends outwardly from a lower end 118 and a camplate 120 that is formed on an upper end 122.

As shown in FIG. 5, the lower end 118 of the coupler body 72 has acircular bottom surface 124. An opening 126 is defined in the bottomsurface 124, and an inner wall 128 extends upwardly from the opening 126to an inner surface 130. The inner wall 128 and the inner surface 130cooperate to define an aperture 132 in the outer shell 114. The aperture132 is sized to receive the upper end 84 of the hinge pin 68, asdescribed in greater detail below.

The coupler body 72 of the hinge assembly 30 also includes an innershaft 134 that extends downwardly from the inner surface 130 of theouter shell 114. The shaft 134 is aligned with the center of thecircular opening 126 and is sized to be received in the passageway 102defined in the hinge pin 68. In the illustrative embodiment, the shaft134 has an outer surface 136 that is cylindrical. It should beappreciated that in other embodiments the shaft 134 may be tapered orkeyed to match the geometric shape of the passageway 102.

As shown in FIG. 5, the coupler body 72 of the hinge assembly 30 has aplurality of ribs 138 that extend from the inner wall 128 into theaperture 132. The ribs 138 are spaced apart equally around thecircumference of the inner wall 128. Each rib 138 has a surface 140 thatengages the outer surface 88 of the cylindrical shaft 82 of the hingepin 68 when the hinge assembly 30 is assembled. In the illustrativeembodiment, the surface 140 is a convex surface. In other embodiments,the surface 140 may be substantially planar. It should also beappreciated that in other embodiments the ribs 138 may be omitted suchthat the inner wall 128 of the coupler body 72 may engage the outersurface 88 of the cylindrical shaft 82 of the hinge pin 68 when thehinge assembly 30 is assembled.

The coupler body 72 also includes a plurality of splines 142 that extendfrom the inner wall 128 into the aperture 132. As shown in FIG. 5, thesplines 142 are positioned between the ribs 138 and spaced apart equallyaround the circumference of the inner wall 128. Each spline 142 is sizedto be received in a corresponding slot 90 of the hinge pin 68 and has across-sectional geometry that is shaped to match the geometry of theslot 90. In the illustrative embodiment, each spline 142 has a convexsurface 144 that matches the concave surface 94 of each slot 90. Thenumber of splines 142 also corresponds to the number of slots 90 definedin the hinge pin 68. Thus, in the illustrative embodiment, the couplerbody 72 has six splines 142. Further, in the illustrative embodiment,two of the six splines are larger than the other splines such that thecoupler body 72 and the hinge pin 68 are keyed and may be coupledtogether in one of two orientations.

Returning to FIG. 2, a cam plate 120 is formed on the upper end 122 ofthe coupler body 72. The cam plate 120 includes a pair of angled camsurfaces 150, 152 that extend downwardly from a substantially-planar topsurface 154 of the outer shell 114 to a base surface 156. The surfaces150, 152, 156 cooperate to define a groove 158 in the upper end 122 ofthe coupler body 72. The cam plate 120 includes another pair of angledcam surfaces 160, 162 positioned on the opposite side of the outer shell114 (see FIG. 8). The cam surfaces 160, 162, like the cam surfaces 150,152, extend downwardly from the substantially-planar top surface 154 toa base surface 166. The surfaces 160, 162, 166 cooperate to define agroove 168 in the upper end 122 of the coupler body 72.

As described above, the lower hinge assembly 30 also includes a bushing70 configured to be secured to the right-hand door 24. As shown in FIGS.2 and 3, the bushing 70 has a body 180 and a flange 182 that extendsoutwardly from a lower end 184. As described in greater detail below,the body 180 is keyed to match the passageway 238 defined in the door24, and includes a rib (not shown) to align the body 180 with the door24. An opening 186 is defined in a bottom surface 188 of the bushing 70,and an inner wall 190 extends upwardly from the opening 186 to an innersurface 190. The inner wall 190 of the body 180 is cylindrical, and theinner wall 190 cooperates with the inner surface 192 define acylindrical aperture 194 in the body 180. The aperture 194 is sized toreceive the upper end 122 of the coupler body 72, as described ingreater detail below.

The bushing 70 also includes a cam plate 200 that is formed on the innersurface 190 of the body 180. The cam plate 200 includes a pair of wedges202 sized to be received in the grooves 158, 168 of the cam plate 120 ofthe coupler body 72. Each wedge 202 includes a pair of angled camsurfaces 204, 206. When the bushing 70 is assembled with the couplerbody 72, the cam surfaces 204, 206 of one wedge 202 engage the camsurfaces 150, 152 of the coupler body 72 and the cam surfaces 204, 206of the other wedge 202 engage the cam surfaces 160, 162 of the couplerbody 72.

As shown in FIG. 3, the body 180 of the bushing 70 has a plurality ofplanar outer side walls 210. In the illustrative embodiment, the body180 has eight side walls 210 such that the outer geometry of the body180 is octagonal. It should be appreciated that in other embodiments thebody 180 may have additional or fewer side walls. The bushing 70 isformed from a polymeric material, such as, for example, acetal. In otherembodiments, the bushing 70 may be formed from a metallic material suchas cold-formed steel.

As shown in FIG. 2, the refrigerator 10 also includes a door stopbracket 214 for the right-hand door 24. The door stop bracket 214 isformed from a metallic material, such as, for example, steel, but itshould be appreciated that in other embodiments the bracket 214 may beformed from a hard polymeric material. The door stop bracket 214 has ahorizontally-extending flange 216 configured to be secured to the door24 and a front flange 218 extending downwardly from the flange 216. Athrough-hole 220 is defined in the flange 216 and is sized to receivethe body 180 of the bushing 70. In the illustrative embodiment, thethrough-hole 220 is defined a plurality of side walls (not shown) andhas an octagonal shape to match the outer geometry of the body 180.

The right-hand door 24 of the refrigerator 10 has a front panel 34 thatis secured to a frame 222. The frame 222 has a slot 224 defined in alower end 226 thereof, and the slot 224 is sized to receive the flange216 of the door stop bracket 214. As shown in FIG. 2, the frame 222includes a plurality of side walls 230 and a lower wall 232 that definethe slot 224. The bracket 214 may be secured to the door 24 via one ormore fasteners (not shown).

The lower wall 232 of the frame 222 has an opening 234 defined therein,and a plurality of inner walls 236 extend upwardly from the opening 234to define a passageway 238 in the frame 222. The passageway 238 is sizedto receive the body 180 of the bushing 70. When the door 24 is assembledwith the hinge assembly 30, the inner walls 236 of the frame 222confront the outer side walls 210 of the bushing 70. In that way,relative axial movement between the bushing 70 and the door 24 isprevented, and the bushing 70 pivots with the door 24 as the door 24moves between the open position and the closed position.

The hinge assembly 30 of the right-hand door 24 further includes anadjustment mechanism 250 configured to move the door 24 verticallyrelative to the cabinet 12. In the illustrative embodiment, theadjustment mechanism 250 includes a rod 252 that is sized to bepositioned in the passageway 102 of the hinge pin 68. The rod 252 has aplurality of external threads 254 defined on an outer surface 256thereof. The external threads 254 of the rod 252 correspond to theinternal threads 106 of the hinge pin 68. When the rod 252 is positionedin the passageway 102, the external threads 254 of the rod 252 engagethe internal threads 106 of the hinge pin 68. The threaded engagementbetween the rod 252 and the hinge pin 68 permits the rod 252 to berotated about the axis 86 extending through the hinge pin 68.

The lower end 258 of the rod 252 has a socket 260 defined therein toreceive a tool that may be used to rotate the rod 252 about the axis 86.When the rod 252 is rotated in the direction indicated by arrow 262, therod 252 is moved upward, toward the upper opening 96. When the rod 252is rotated in the opposite direction, the rod 252 is moved downward,toward the lower opening 98 of the hinge pin 68. Because the upper innersurface 108 of hinge pin 68 is smooth, the rod 252 is prevented fromadvancing beyond a predetermined position in the passageway 102. In thatway, the upper inner surface 108 is a travel stop 264 for the adjustmentmechanism 250. It should be appreciated that in other embodiments thehinge pin 68, for example, may include one or more tabs, lips, or otherstructures to provide a mechanical stop for the adjustment mechanism250.

To assemble the hinge assembly 30, the hinge pin 68 is attached to themounting plate 48. To do so, the tail 78 of the hinge pin 68 is alignedwith the bore 58 of the mounting plate 48. The hinge pin 68 is advanceddownward so that the tail 78 is received in the bore 58, and the flange76 is moved into contact with the upper surface 50 of the mounting plate48. In the illustrative embodiment, the tail 78 is swaged to shape thelower end 80 of the tail 78 into a circular flange 270, as shown in FIG.2. The circular flange 270 is engaged with the lower surface 52 of themounting plate 48, and the mounting plate 48 is clamped between theflanges 76, 270 of the hinge pin 68 to join the hinge pin 68 and themounting plate 48 together. The engagement between the flanges 76, 270and the mounting plate 48 fix the hinge pin 68 in position and preventthe hinge pin 68 from rotating about the axis 86. It should beappreciated that in other embodiments the hinge pin 68 may be joined tothe mounting plate 48 by welding, a mechanical fastener, or other means.

When the hinge pin 68 is secured to the mounting plate 48, the couplerbody 72 of the hinge assembly 30 is positioned above the hinge pin 68.The cylindrical shaft 82 is aligned with the aperture 132 defined in thecoupler body 72, and the splines 142 of the coupler body 72 are alignedwith the slots 90 defined in the hinge pin 68. The coupler body 72 ismoved downward, and the inner shaft 134 of the coupler body 72 isadvanced into the passageway 102 of the hinge pin 68 as the shaft 82 ismoved into the aperture 132. Additionally, each spline 142 is advancedinto one of the slots 90.

To attach the bushing 70 to the coupler body 72, the bushing 70 ispositioned above the coupler body 72 such that the outer shell 114 isaligned with the aperture 194 defined in the bushing 70. The bushing 70is moved downward to position the outer shell 114 in the aperture 194and to engage the cam plate 120 of the coupler body 72 with the camplate 200 of the bushing 70. The bushing 70 may be rotated about thelongitudinal axis 86 to advance the wedges 202 of the cam plate 200 intothe grooves 158, 168 of the cam plate 120.

It should be appreciated that the bushing 70 may be secured to the frame222 of the right-hand door 24 before or after the bushing 70 is attachedto the coupler body 72. To do so, the door 24 is positioned above thebushing 70, and the body 180 of the bushing 70 is aligned with thepassageway 238 defined the frame 222. The door 24 may be moved downward(or the bushing 70 upward) to advance the bushing 70 into the passageway238. As described above, the inner walls 236 of the frame 222 engage theouter side walls 210 of the bushing 70 when the bushing 70 is attachedto the door 24, thereby preventing relative axial movement between thebushing 70 and the door 24. When the door 24 is properly seated on thebushing 70, the lower flange 182 of the bushing 70 engages the flange216 of the door stop bracket 214, as shown in FIG. 6.

When the door 24 and the hinge assembly 30 are coupled together, theadjustment mechanism 250 may be used to change the vertical position ofthe door 24. To do so, the rod 252 may be attached to the lower end 80of the hinge pin 68 and a wrench or other tool may be attached to thesocket 260 of the rod 252. The wrench may be used to rotate the rod 252about the axis 86 in the direction indicated by arrow 262 to move therod 252 upward along the passageway 102 of the hinge pin 68. As the rod252 is moved upward, the upper end 280 of the rod 252 is advanced intocontact with the lower end 282 of the inner shaft 134 of the couplerbody 72. When the rod 252 is engaged with the coupler body 72, continuedupward movement of the rod 252 causes the coupler body 72, the bushing70, and the door 24 to move upward to the position shown in FIG. 6.

As shown in FIG. 6, the front panel 34 of the right-hand door 24 has alower end 284 positioned in front of the flange 218 of the door stopbracket 214. The front panel 34 also has a bottom surface 286 that facesa top surface 288 of the drawer 20 of the refrigerator 10. A gap 290 isdefined between the surfaces 286, 288 when the door 24 is attached tothe hinge assembly 30. As shown in FIG. 6, the gap 290 has a magnitude292 of approximately twelve millimeters.

The size of the gap 290 corresponds to the vertical position of the door24 relative to the cabinet 12. The adjustment mechanism 250 may be usedto move the right-hand door 24 higher or lower from the position shownin FIG. 6, and thereby change the size of the gap 290. To do so, the rod252 may be rotated about the axis 86 in the direction indicated by arrow262 to move the rod 252 upward along the passageway 102 of the hinge pin68. As described above, the upward movement of the rod 252 causes thecoupler body 72, the bushing 70, and the door 24 to move upward. Whenthe rod 252 reaches the travel stop 264, as shown in FIG. 7, the travelstop 264 prevents further upward movement of the rod 252. In thatposition, the gap 290 has a magnitude 292 of approximately sixteenmillimeters. In that way, the door 24 may be lifted approximately threemillimeters between the position shown in FIG. 6 and the position shownin FIG. 7.

When the rod 252 is rotated about the axis 86 in the direction indicatedby arrow 294, the rod 252 may be moved downward along the passageway 102of the hinge pin 68. The movement of the rod 252 causes the coupler body72, the bushing 70, and the door 24 to move downward until the innersurface 130 of the coupler body 72 is advanced into contact with theupper end 84 of the hinge pin 68, thereby preventing further downwardmovement of the hinge assembly 30 and the door 24. In that position, thegap 290 has a magnitude of approximately ten millimeters. Thus, in theillustrative embodiment, the vertical position of the door 24 relativeto the drawer 20 (and hence the cabinet 12) may be adjusted byapproximately six millimeters.

As described above, the right-hand door 24 may be pivoted about the axis86 to move the door 24 between the open position and the closedposition. When the door 24 is in the closed position, the cam surfaces204, 206 of the wedges 202 of the cam plate 200 of the bushing 70confront the corresponding cam surfaces 150, 152, 160, 162 of the camplate 120 of the coupler body 72. When the door 24 is opened, the door24 is pivoted about the axis 86 as indicated by arrow 296 in FIG. 8. Asthe door 24 is pivoted, the wedges 202 of the cam plate 200 apply a loadto the cam surfaces 150, 160 of the coupler body 72 in the directionindicated by arrows 298 in FIG. 8.

The load is transferred through the coupler body 72 to the hinge bracket40 via the hinge pin 68. The engagement between the splines 142 of thecoupler body 72 and the slots 90 of the hinge pin 68 prevents thecoupler body 72 from pivoting with the door 24 and the bushing 70. As aresult, the wedges 202 of the bushing 70 slide upwardly along the camsurfaces 150, 160 of the coupler body 72 as the door 24 is pivoted aboutthe axis 86, thereby lifting the door 24 as the door 24 is opened. Whenthe door 24 is moved to the open position, the door stop bracket 214 isadvanced into the pocket 62 defined in the mounting plate 48. The doorstop bracket 214 engages the side wall 62 and the flange 64 such thatfurther movement of the door 24 about the axis 86 is prevented.

When the door 24 is moved from the open position to the closed position,the wedges 202 of the bushing 70 advance along the top surfaces 154 ofthe cam plate 120 of the coupler body 72 and then downward along the camsurfaces 150, 160 of the lower cam plate 120 such that the door 24 islowered as the door 24 is moved to the closed position.

As described above, the refrigerator 10 also includes a left-hand door26 that is hinged to the front of the cabinet 12 via an upper hingeassembly 28 and a lower hinge assembly 36. Referring now to FIG. 9, thelower hinge assembly 36 is configured to be secured to a hinge bracket340. The hinge bracket 340 is formed from a metallic material, such as,for example, steel, and is sized to support the weight of the left-handdoor 26. The hinge bracket 340, like the hinge bracket 40, includes avertical flange 342 configured to be attached to the front wall 44 ofthe cabinet 12 via a plurality of bolts (not shown), which extendthrough holes 46 formed in the flange 342 and engage the cabinet 12. Thehinge bracket 340 also includes a mounting plate 348 that extendshorizontally from the flange 342.

The mounting plate 348 of the hinge bracket 340 extends outwardly fromthe cabinet 12 when the bracket 340 is secured to the cabinet 12. Themounting plate 348 has an upper surface 350 and a lower surface 352positioned opposite the upper surface 350. As shown in FIG. 10, anopening 354 is defined in the upper surface 350 of the mounting plate348, and an inner wall 356 extends downwardly from the opening 354 todefine a bore 358 through the mounting plate 348. In the illustrativeembodiment, the opening 354 is circular, and the bore 358 issubstantially cylindrical. It should be appreciated that in otherembodiments the opening may be oblong, square, or other geometricshapes.

The lower hinge assembly 36 of the left-hand door 26 includes a hingepin 368 configured to be secured to the hinge bracket 340, a bushing 70configured to be secured to the left-hand door 26, and a coupler body 72positioned between the hinge pin 368 and the bushing 70. As shown inFIG. 9, the hinge pin 368 has a body 374 and a flange 376 that extendsoutwardly from the body 374. The body 374 has a tail 378 that extendsdownwardly from the flange 376 to a lower end 380. The tail 378 has across-sectional geometry that is shaped to match the bore 358 of themounting plate 348. In the illustrative embodiment, the tail 378 iscylindrical and has an outer diameter that is sized such that the tail378 may be received in the bore 358.

The body 374 of the hinge pin 368 includes a cylindrical shaft 382,which extends upwardly from the flange 376 to an upper end 384. Theshaft 382 defines a vertically-extending longitudinal axis 386 of thehinge pin 368, and the left-hand door 26 is configured to pivot aboutthe axis 86 between the open and closed positions when the hingeassembly 36 and the door 26 are assembled (see FIG. 10). The shaft 382of the pin body 374 has an outer surface 388 and a plurality of groovesor slots 390 defined in the outer surface 388. As shown in FIG. 9, eachslot 390 has an opening 392 defined in the upper end 384 of the body374. A concave surface 394 extends downwardly from each opening 392 andinwardly from the outer surface 388 to define each slot 390. The slots390 extend parallel to the axis 86 and are spaced equally apart from oneanother around the outer circumference of the cylindrical shaft 382. Inthe illustrative embodiment, the hinge pin 368 includes six slots 390,but it should be appreciated that in other embodiments the hinge pin 368may include additional or fewer slots.

As shown in FIG. 10, the body 374 of the hinge pin 368 has an opening396 defined in the upper end 384 and another opening 398 defined in thelower end 380. An inner wall 400 extends between the openings 396, 398to define a cylindrical passageway 402 through the hinge pin 368. Thesurface 404 of the inner wall 400 is substantially smooth.

As described above, the lower hinge assembly 36 also includes a couplerbody 72 that is configured to be engaged with the hinge pin 368. In theillustrative embodiment, the coupler body 72 used in the lower hingeassembly 36 of the left-hand door 26 is identical to the coupler body 72used in the lower hinge assembly 30 of the right-hand door 24.Similarly, the bushing 70 used in the lower hinge assembly 36 of theleft-hand door 26 is identical to the bushing 70 used in the lower hingeassembly 30 of the right-hand door 24.

As shown in FIG. 2, the refrigerator 10 also includes a door stopbracket 414 for the left-hand door 26. The door stop bracket 414 has ahorizontally-extending flange 416 configured to be secured to the door24 and a front flange 418 extending downwardly from the flange 416. Athrough-hole 420 is defined in the flange 416 and, like the through-hole220 of the door stop bracket 214, is sized to receive the body 180 ofthe bushing 70. In the illustrative embodiment, the through-hole 420 isdefined a plurality of side walls (not shown) and has an octagonal shapeto match the outer geometry of the body 180.

The left-hand door 26 of the refrigerator 10 has a front panel 38 thatis secured to a frame 422. The frame 422 has a slot 424 defined in alower end 426 thereof that is sized to receive the flange 416 of thedoor stop bracket 414. As shown in FIG. 10, the frame 422 includes aplurality of side walls 430 and a lower wall 432 that define the slot424. The bracket 414 may be secured to the door 26 via one or morefasteners (not shown).

The lower wall 432 of the frame 422 has an opening 434 defined therein,and a plurality of inner walls 436 define a passageway 438 in the frame422. The passageway 438 is sized to receive the body 180 of the bushing70. When the door 26 is assembled with the hinge assembly 36, the innerwalls 436 of the frame 422 confront the outer side walls 410 of thebushing 70, as shown in FIG. 10. In that way, relative axial movementbetween the bushing 70 and the door 26 is prevented such that thebushing 70 pivots with the door 26 as the door 26 moves between the openposition and the closed position.

To assemble the hinge assembly 36, the hinge pin 368 is attached to themounting plate 348. To do so, the tail 378 of the hinge pin 368 isaligned with the bore 358 of the mounting plate 348. The hinge pin 368is advanced downward so that the tail 378 is received in the bore 358,and the flange 376 is moved into contact with the upper surface 350 ofthe mounting plate 348. In the illustrative embodiment, the tail 378 isswaged to shape the lower end 380 of the tail 378 into a circular flange470, as shown in FIG. 10. The circular flange 470 is engaged with thelower surface 352 of the mounting plate 348. The mounting plate 348 isclamped between the flanges 376, 470 of the hinge pin 368, therebyjoining the hinge pin 368 and the mounting plate 348 together. It shouldbe appreciated that in other embodiments the hinge pin 368 may be joinedto the mounting plate 348 by welding, a mechanical fastener, or othermeans.

When the hinge pin 368 is secured to the mounting plate 348, the couplerbody 72 of the hinge assembly 30 is positioned above the hinge pin 368.The cylindrical shaft 382 of the hinge pin 368 is aligned with theaperture 132 defined in the coupler body 72, and the splines 142 of thecoupler body 72 are aligned with the slots 390 defined in the hinge pin368. The coupler body 72 is moved downward, and the inner shaft 134 ofthe coupler body 72 is advanced into the passageway 402 of the hinge pin368 as the shaft 382 of the hinge pin 368 is received in the aperture132. Additionally, the each spline 142 of the coupler body 72 isadvanced into one of the slots 390.

The bushing 70 may be attached to the coupler body 72 as describedabove. It should be appreciated that the bushing 70 may be secured tothe frame 422 of the left-hand door 26 before or after the bushing 70 isattached to the coupler body 72. To do so, the door 26 is positionedabove the bushing 70 such that the body 180 of the bushing 70 is alignedwith the passageway 438 defined the frame 422. The door 26 may be moveddownward (or the bushing 70 upward) to advance the bushing 70 into thepassageway 438. As described above, the inner walls 436 of the frame 422engage the outer side walls 210 of the bushing 70 when the bushing 70 isattached to the door 26, thereby preventing relative axial movementbetween the bushing 70 and the door 26. When the door 26 is properlyseated on the bushing 70, the lower flange 182 of the bushing 70 engagesthe flange 416 of the door stop bracket 414, as shown in FIG. 10.

The front panel 38 of the left-hand door 26 has a lower end 484positioned in front of the flange 418 of the door stop bracket 414. Thefront panel 38 also has a bottom surface 486 that faces a top surface288 of the drawer 20 of the refrigerator 10. A gap 490 is definedbetween the surfaces 486, 288 when the door 26 is attached to the hingeassembly 36. As shown in FIG. 10, the gap 490 has a magnitude 492 ofapproximately thirteen millimeters.

As described above, the left-hand door 26 may be pivoted about the axis386 to move the door 26 between the closed position and the openposition. When the door 26 is opened, the door 26 is pivoted about theaxis 386 and a load is applied to the coupler body 72 by the cam plate200 of the bushing 70. The engagement between the splines 142 of thecoupler body 72 and the slots 390 of the hinge pin 368 prevents thecoupler body 72 from pivoting with the door 26 and the bushing 70. Aswith the lower hinge assembly 30 of the right-hand door 24, theinteraction between the coupler body 72 and the bushing 70 lifts thedoor 26 as the door 26 is moved between positions.

Referring now to FIGS. 11-14, another embodiment of a lower hingeassembly (hereinafter lower hinge assembly 530) is illustrated. Somefeatures of the embodiment illustrated in FIGS. 11-14 are substantiallysimilar to those discussed above in reference to the embodiment of FIGS.1-9. Such features are designated in FIGS. 11-14 with the same referencenumbers as those used in FIGS. 1-9.

The lower hinge assembly 530 is configured to be secured to a hingebracket 40. As shown in FIG. 11, the hinge bracket 40 includes avertical flange 42 and a mounting plate 48 that extends horizontallyfrom the flange 42. The mounting plate 48 has an upper surface 50 and alower surface 52 positioned opposite the upper surface 50. An opening 54is defined in the upper surface 50 of the mounting plate 48, and aninner wall 56 extends downwardly from the opening 54 to define a bore 58through the mounting plate 48.

As shown in FIGS. 11-14, the lower hinge assembly 530 includes a hingepin 568 configured to be secured to the hinge bracket 40, a bushing 70configured to be secured to the right-hand door 24, and a coupler body572 positioned between the hinge pin 568 and the bushing 70. As shown inFIG. 12, the hinge pin 568 has a body 574 and a circular flange 76 thatextends outwardly from the body 574. The body 574 has a tail 78 thatextends downwardly from the circular flange 76 to a lower end 80. Thetail 78 has a cross-sectional geometry that is shaped to match the bore58 of the mounting plate 48. In the illustrative embodiment, the tail 78is cylindrical and has an outer diameter that is sized such that thetail 78 may be received in the bore 58.

The body 574 of the hinge pin 568 includes a cylindrical shaft 582,which extends upwardly from the circular flange 76 to an upper end 584.The shaft 582 defines a vertically-extending longitudinal axis 86 of thehinge pin 568. As described in greater detail below, the right-hand door24 is configured to pivot about the axis 86 to move between the closedposition and the open position when the hinge assembly 30 and the door24 are assembled. The shaft 582 of the pin body 574 has an outer surface588 that includes a pair of substantially planar surfaces 590, 592 and apair of convex surfaces 594, 596. The surfaces 594, 596 extend betweenthe surfaces 590, 592 and connect the surfaces 590, 592 to one another.

The body 574 of the hinge pin 568 has an opening 600 defined in theupper end 584 and another opening 602 defined in the lower end 80. Aninner wall 604 extends between the openings 600, 602 to define acylindrical passageway 606 through the hinge pin 568. The inner wall 604of the body 574 includes a lower surface 104 having a number of internalthreads 106 defined therein and an upper surface 610 positioned abovethe lower surface 104. The upper surface 610 of the inner wall 604 istapered and substantially smooth.

In the illustrative embodiment, the hinge pin 568 is formed as a singlemonolithic component from a metallic material, such as, for example,cold-formed steel. In other embodiments, the body 574 and the circularflange 76 may be formed as separate components that are assembled. Itshould be appreciated that the configuration of one or more of thosecomponents of the hinge pin 568 may be modified in other embodiments. Itshould further be appreciated that in other embodiments one or more ofthe components may be made from a polymeric material, such as, forexample, a rigid plastic.

As described above, the lower hinge assembly 530 also includes a couplerbody 572 that is configured to be engaged with the hinge pin 568.Returning to FIG. 11, the coupler body 572 includes an outer shell 614formed from a polymeric material, such as, for example, nylon. It shouldbe appreciated that in other embodiments the outer shell 614 may beformed from a metallic material, such as, for example, cold-rolledsteel. The outer shell 614 has a flange 116 that extends outwardly froma lower end 618 and a cam plate 120 that is formed on an upper end 122.

As shown in FIG. 13, the lower end 618 of the coupler body 72 has acircular bottom surface 624. An opening 626 is defined in the bottomsurface 624, and an inner wall 628 extends upwardly from the opening 626to an inner surface 630. The inner wall 628 and the inner surface 630cooperate to define an aperture 632 in the outer shell 614. The aperture632 is sized to receive the upper end 584 of the hinge pin 568, asdescribed in greater detail below.

The coupler body 572 of the hinge assembly 530 also includes an innershaft 634 that extends downwardly from the inner surface 630 of theouter shell 614. The shaft 634 is aligned with the center of thecircular opening 626 and is sized to be received in the passageway 606defined in the hinge pin 568. In the illustrative embodiment, the shaft634 has an outer surface 636 that is tapered and has a plurality oflongitudinal grooves 638 defined therein. It should be appreciated thatin other embodiments the shaft 634 may be cylindrical or keyed to matchthe geometric shape of the passageway 606.

As shown in FIG. 13, the coupler body 72 of the hinge assembly 530 has aplurality of ribs 640 that extend from the inner wall 628 into theaperture 632. The ribs 640 are spaced apart around the circumference ofthe inner wall 628. Each rib 640 has a surface 642 that engages one ofthe pair of convex surfaces of 594, 596 of the hinge pin 568 when thehinge assembly 530 is assembled. In the illustrative embodiment, thesurface 642 of the rib 640 is a convex surface. In other embodiments,the surface 642 may be substantially planar. It should also beappreciated that in other embodiments the ribs 640 may be omitted suchthat the inner wall 628 of the coupler body 572 may engage the convexsurfaces of 594, 596 of the hinge pin 68 when the hinge assembly 530 isassembled.

The inner wall 628 of the coupler body 572 has a pair of substantiallyplanar surfaces 650, 652. As shown in FIG. 13, the surfaces 650, 652 arepositioned on opposite sides of the inner shaft 634. The surfaces 650,652 are configured to engage the surfaces 590, 592, respectively, of thehinge pin 568. The number of substantially planar surfaces formed on thecoupler body 572 corresponds to the number of substantially planarsurfaces formed on the hinge pin 568.

Returning to FIG. 11, a cam plate 120 is formed on the upper end 122 ofthe coupler body 572. The cam plate 120 includes a pair of angled camsurfaces 150, 152 that extend downwardly from a substantially-planar topsurface 154 of the outer shell 114 to a base surface 156. As shown inFIG. 14, the surfaces 150, 152, 156 cooperate to define a groove 158 inthe upper end 122 of the coupler body 72. The cam plate 120 includesanother pair of angled cam surfaces 160, 162 positioned on the oppositeside of the outer shell 614. The cam surfaces 160, 162, like the camsurfaces 150, 152, extend downwardly from the substantially-planar topsurface 154 to a base surface 166. The surfaces 160, 162, 166 cooperateto define a groove 168 in the upper end 122 of the coupler body 572.

As described above, the lower hinge assembly 530 also includes a bushing70 configured to be secured to the right-hand door 24. As shown in FIG.11, the bushing 70 has a body 180 and a flange 182 that extendsoutwardly from a lower end 184. The bushing 70 has a cylindricalaperture 194 defined therein that is sized to receive the upper end 122of the coupler body 572.

The bushing 70 also includes a cam plate 200 that is formed on the innersurface 190 of the body 180. The cam plate 200 includes a pair of wedges202 sized to be received in the grooves 158, 168 of the cam plate 120 ofthe coupler body 572. Each wedge 202 includes a pair of angled camsurfaces 204, 206. When the bushing 70 is assembled with the couplerbody 572, the cam surfaces 204, 206 of one wedge 202 engage the camsurfaces 150, 152 of the coupler body 572 and the cam surfaces 204, 206of the other wedge 202 engage the cam surfaces 160, 162 of the couplerbody 572.

As shown in FIG. 11, the door 24 has a front panel 34 that is secured toa frame 222. The refrigerator 10 also includes a door stop bracket 214for the right-hand door 24 that is secured to the frame 222 via one ormore fasteners (not shown). The frame 222 includes a passageway 238 thatis sized to receive the body 180 of the bushing 70. When the door 24 isassembled with the hinge assembly 530, the inner walls 236 of the frame222 confront the outer side walls 210 of the bushing 70. In that way,relative axial movement between the bushing 70 and the door 24 isprevented, and the bushing 70 pivots with the door 24 as the door 24moves between the open position and the closed position.

The hinge assembly 530 further includes an adjustment mechanism 680configured to move the door 24 vertically relative to the cabinet 12. Inthe illustrative embodiment, the adjustment mechanism 680 includes a rod252 that is sized to be positioned in the passageway 606 of the hingepin 568. The rod 252 has a plurality of external threads 254 defined onan outer surface 256 thereof. The external threads 254 of the rod 252correspond to the internal threads 106 of the hinge pin 568. When therod 252 is positioned in the passageway 606, the external threads 254 ofthe rod 252 engage the internal threads 106 of the hinge pin 68. Thethreaded engagement between the rod 252 and the hinge pin 68 permits therod 252 to be rotated about the axis 86 extending through the hinge pin68.

The lower end 258 of the rod 252 has a socket 260 defined therein toreceive a tool that may be used to rotate the rod 252 about the axis 86.When the rod 252 is rotated in the direction indicated by arrow 262, therod 252 is moved upward, toward the upper opening 600. When the rod 252is rotated in the opposite direction, the rod 252 is moved downward,toward the lower opening 602 of the hinge pin 568. Because the upperinner surface 610 of hinge pin 568 is smooth and tapered, the rod 252 isprevented from advancing beyond a predetermined position in thepassageway 606. In that way, the upper inner surface 610 is a travelstop 682 for the adjustment mechanism 680. It should be appreciated thatin other embodiments the hinge pin 568, for example, may include one ormore tabs, lips, or other structures to provide a mechanical stop forthe adjustment mechanism 680.

As described above, the right-hand door 24 may be pivoted about the axis86 to move the door 24 between the open position and the closedposition. When the door 24 is in the closed position, the cam surfaces204, 206 of the wedges 202 of the cam plate 200 of the bushing 70confront the corresponding cam surfaces 150, 152, 160, 162 of the camplate 120 of the coupler body 572. When the door 24 is opened, the door24 is pivoted about the axis 86 as indicated by arrow 296 in FIG. 14. Asthe door 24 is pivoted, the wedges 202 of the cam plate 200 apply a loadto the cam surfaces 150, 160 of the coupler body 572 in the directionindicated by arrows 298 in FIG. 14.

The load is transferred through the coupler body 572 to the hingebracket 40 via the hinge pin 568. The engagement between the surfaces650, 652 of the coupler body 572 and the surfaces 590, 592,respectively, of the hinge pin 568 prevents the coupler body 572 frompivoting with the door 24 and the bushing 70. As a result, the wedges202 of the bushing 70 slide upwardly along the cam surfaces 150, 160 ofthe coupler body 572 as the door 24 is pivoted about the axis 86,thereby lifting the door 24 as the door 24 is opened.

When the door 24 is moved to from the open position to the closedposition, the wedges 202 of the bushing 70 advance along the topsurfaces 154 of the cam plate 120 of the coupler body 572 and thendownward along the cam surfaces 150, 160 of the lower cam plate 120 suchthat the door 24 is lowered as the door 24 is moved to the closedposition.

Referring now to FIGS. 15-20, another embodiment of a lower hingeassembly (hereinafter lower hinge assembly 700) is illustrated. Somefeatures of the embodiment illustrated in FIGS. 15-20 are substantiallysimilar to those discussed above in reference to the embodiment of FIGS.1-9. Such features are designated in FIGS. 15-20 with the same referencenumbers as those used in FIGS. 1-9.

The lower hinge assembly 700 is configured to be secured to a hingebracket 40. As shown in FIG. 15, the hinge bracket 40 includes avertical flange 42 and a mounting plate 48 that extends horizontallyfrom the flange 42. The mounting plate 48 has an upper surface 50 and alower surface 52 positioned opposite the upper surface 50. An opening 54is defined in the upper surface 50 of the mounting plate 48, and aninner wall 56 extends downwardly from the opening 54 to define a bore 58through the mounting plate 48.

As shown in FIG. 15, the lower hinge assembly 700 includes a hinge pin68 configured to be secured to the hinge bracket 40, a closer assembly702 configured to be coupled to the door 24, a coupler body 704configured to be coupled to the hinge bracket 40 and the closer assembly702, and a spacer 706. The coupler body 704 configured to be positionedbetween the spacer 706 and the closer assembly 702, as described ingreater detail below. The spacer 706 is configured to be positionedabove the flange 76 of the hinge pin 68 to vertically offset the couplerbody 74 from the flange 76.

Referring now to FIG. 16, the hinge pin 68 has a body 74 and a circularflange 76 that extends outwardly from the body 74. The body 74 has atail 78 that extends downwardly from the circular flange 76 to a lowerend 80. The tail 78 has a cross-sectional geometry that is shaped tomatch the bore 58 of the mounting plate 48. In the illustrativeembodiment, the tail 78 is cylindrical and has an outer diameter that issized such that the tail 78 may be received in the bore 58.

The body 74 of the hinge pin 68 includes a cylindrical shaft 82, whichextends upwardly from the circular flange 76 to an upper end 84. Theshaft 82 defines a vertically-extending longitudinal axis 86 of thehinge pin 68. As described in greater detail below, the right-hand door24 is configured to pivot about the axis 86 to move between the closedposition and the open position when the hinge assembly 700 and the door24 are assembled. The shaft 82 of the pin body 74 has an outer surface88 and a plurality of grooves or slots 90 defined in the outer surface88. As shown in FIG. 16, each slot 90 has an opening 92 defined in theupper end 84 of the body 74. A concave surface 94 extends downwardlyfrom each opening 92 and inwardly from the outer surface 88 to defineeach slot 90. The slots 90 extend parallel to the axis 86 and are spacedapart equally from one another around the outer circumference of thecylindrical shaft 82. In the illustrative embodiment, the hinge pin 68includes six slots 90, but it should be appreciated that in otherembodiments the hinge pin 68 may include additional or fewer slots.

Returning to FIG. 15, the body 74 of the hinge pin 68 has an opening 96defined in the upper end 84 and another opening 98 defined in the lowerend 80. An inner wall 100 extends between the openings 96, 98 to definea cylindrical passageway 102 through the hinge pin 68. The inner wall100 of the body 74 includes a lower surface 104 having a number ofinternal threads 106 defined therein and an upper surface 108 that ispositioned above the lower surface 104. The upper surface 108 of theinner wall 100 is substantially smooth.

In the illustrative embodiment, the hinge pin 68 is formed as a singlemonolithic component from a metallic material, such as, for example,cold-formed steel. In other embodiments, the body 74 and the circularflange 76 may be formed as separate components that are assembled. Itshould be appreciated that the configuration of one or more of thosecomponents of the hinge pin 68 may be modified in other embodiments. Itshould further be appreciated that in other embodiments one or more ofthe components may be made from a polymeric material, such as, forexample, a rigid plastic.

As described above, the lower hinge assembly 700 also includes a couplerbody 704 that is configured to be engaged with the hinge pin 68. Asshown in FIG. 15, the coupler body 704 includes an outer shell 114formed from a polymeric material, such as, for example, nylon. It shouldbe appreciated that in other embodiments the outer shell 114 may beformed from a metallic material, such as, for example, cold-rolledsteel. The outer shell 114 has a flange 116 that extends outwardly froma lower end 118 and an opening 708 defined in an upper end 710. As shownin FIG. 17, the lower end 118 of the coupler body 704 has a circularbottom surface 124. An opening 126 is defined in the bottom surface 124,and an inner wall 128 extends upwardly from the opening 126 to an innersurface 130. The inner wall 128 and the inner surface 130 cooperate todefine an aperture 132 in the outer shell 114. The aperture 132 is sizedto receive the upper end 84 of the hinge pin 68, as described in greaterdetail below.

The coupler body 704 of the lower hinge assembly 700 also includes aninner shaft 134 that extends downwardly from the inner surface 130 ofthe outer shell 114. The shaft 134 is aligned with the center of thecircular opening 126 and is sized to be received in the passageway 102defined in the hinge pin 68. In the illustrative embodiment, the shaft134 has an outer surface 136 that is cylindrical. It should beappreciated that in other embodiments the shaft 134 may be tapered orkeyed to match the geometric shape of the passageway 102.

The coupler body 704 also includes a plurality of splines 142 thatextend from the inner wall 128 into the aperture 132. As shown in FIG.17, the splines 142 are positioned between ribs 138 and spaced apartequally around the circumference of the inner wall 128. Each spline 142is sized to be received in a corresponding slot 90 of the hinge pin 68and has a cross-sectional geometry that is shaped to match the geometryof the slot 90. In the illustrative embodiment, each spline 142 has aconvex surface 144 that matches the concave surface 94 of each slot 90.The number of splines 142 also corresponds to the number of slots 90defined in the hinge pin 68. Thus, in the illustrative embodiment, thecoupler body 704 has six splines 142. Further, in the illustrativeembodiment, two of the six splines are larger than the other splinessuch that the coupler body 704 and the hinge pin 68 are keyed and may becoupled together in one of two orientations.

As described above, the coupler body 704 has the opening 708 is formedin the upper end 710 thereof, as shown in FIG. 16. The upper end 710 ofthe coupler body 704 has a circular top surface 714. An inner wall 716extends downwardly from the opening 708 to define an aperture 712 in thecoupler body 704. The aperture 712 includes an upper chamber 718 and alower chamber 720 having a smaller cross-sectional diameter than theupper chamber 718. As described in greater detail below, the aperture712 is sized to receive a portion of a shaft 722 of the closer assembly702.

The coupler body 704 also includes a plurality of splines 724 thatextend from the inner wall 716 into the upper chamber 718 of theaperture 712. A slot 726 is defined between each pair of splines 724. Inthe illustrative embodiment, the splines 724 are spaced apart equallyaround the circumference of the inner wall 716, and each spline 724 hasa convex surface 728. Further, in the illustrative embodiment, thecoupler body 704 has six splines 724 extending into the upper chamber718.

As described above, the lower hinge assembly 700 also includes a closerassembly 702 configured to be secured to the right-hand door 24. Asdescribed above, the closer assembly 702 includes a shaft 722 that isconfigured to engage the coupler body 704. The shaft 722 has a base 730and an alignment pin 732 that extends downwardly from the base 730. Whenthe lower hinge assembly 700 is assembled, the base 730 of the shaft 722is received in the upper chamber 718 of the coupler body 704 and thealignment pin 732 is received in the lower chamber 720 of the couplerbody 704.

As shown in FIG. 16, the base 730 has a plurality of slots 734 definedtherein that correspond to the splines 724 of the coupler body 704. Aspline 736 is defined between each slot 734, which corresponds to eachslot 726 defined in the coupler body 704. The slots 734 of the shaft 722receive and confront the splines 724 of the coupler body 704 and theslots 726 of the coupler body 704 receive and confront the splines 736of the shaft 722. In that way, relative axial movement between the shaft722 and the coupler body 704 is prevented. It should be appreciated thatin other embodiments, the base 730 of the shaft 722 and the coupler body704 may be keyed with a different geometrical shape.

The shaft 722 of the closer assembly 702 is secured to an adaptor 738positioned in a housing 740. As shown in FIG. 15, the housing 740includes a casing 742 that extends from a lower end 744 of the housing740 to an upper end 746 thereof. The housing 740 also includes an arm748 that extends outwardly from the casing 742 at the lower end 744 ofthe housing 740. An opening 750 is defined in the lower end 744 of thehousing 740, and the casing 742 includes a number of inner walls 752that extend upwardly from the opening 750 to define an aperture 754 inthe casing 742.

The adaptor 738 of the closer assembly 702 is positioned in the aperture754 and is configured to pivot relative to the casing 742 about the axis86 defined by the hinge pin 68. The closer assembly 702 includes abiasing element, such as, for example, torsional spring 756, that isconfigured to resist the rotation of the adaptor 738 (and hence shaft722) about the axis 86. The spring 756 has an upper end 758 that isfixed to the casing 742 and a lower end 760 secured to the adaptor 738.

As shown in FIG. 15, the door 24 has a front panel 34 that is secured toa frame 762. The refrigerator 10 also includes a door stop bracket 214for the right-hand door 24 that is secured to the frame 762 via one ormore fasteners (not shown). The frame 762 includes the passageway 238that is sized to receive the casing 742 of the housing 740. In theillustrative embodiment, the casing 742 has a plurality of ribs 766formed thereon that are sized to be received in a correspondingplurality of slots 768 defined in the frame 762. Each rib 766 has across-sectional geometry that is shaped to match the geometry of acorresponding slot 768, and the number of ribs 766 also corresponds tothe number of slots 768 defined in the frame 762. In that way, relativeaxial movement between the casing 742 and the door 24 is prevented. Itshould be appreciated that in other embodiments, the casing 742 and thedoor 24 may be keyed with a different geometrical shape.

As shown in FIG. 15, the hinge assembly 700 further includes anadjustment mechanism 250 configured to move the door 24 verticallyrelative to the cabinet 12. In the illustrative embodiment, theadjustment mechanism 250 includes a rod 252 that is sized to bepositioned in the passageway 102 of the hinge pin 68. The rod 252 has aplurality of external threads 254 defined on an outer surface 256thereof. The external threads 254 of the rod 252 correspond to theinternal threads 106 of the hinge pin 68. When the rod 252 is positionedin the passageway 102, the external threads 254 of the rod 252 engagethe internal threads 106 of the hinge pin 68. The threaded engagementbetween the rod 252 and the hinge pin 68 permits the rod 252 to berotated about the axis 86 extending through the hinge pin 68.

Referring now to FIGS. 18 and 19, a lower end 258 of the rod 252 has asocket 260 defined therein to receive a tool that may be used to rotatethe rod 252 about the axis 86. When the rod 252 is rotated in thedirection indicated by arrow 772, the rod 252 is moved upward, towardthe upper opening 96 as shown in FIG. 18. When the rod 252 is rotated inthe opposite direction, the rod 252 is moved downward, toward the loweropening 98 of the hinge pin 68 as shown in FIG. 19. In the illustrativeembodiment, the upper inner surface 108 of hinge pin 68 is smooth andtapered as shown in FIG. 15. As such, the rod 252 is prevented fromadvancing beyond a predetermined position in the passageway 102. In thatway, the upper inner surface 108 is a travel stop 774 for the adjustmentmechanism 250. It should be appreciated that in other embodiments, thehinge pin 68, for example, may include one or more tabs, lips, or otherstructures to provide a mechanical stop for the adjustment mechanism250.

As described above, the right-hand door 24 may be pivoted about the axis86 to move the door 24 between the open position and the closedposition. When the door 24 is in the closed position, the splines 142 ofthe coupler body 704 confront the corresponding slots 90 of the hingepin 68. Likewise, the splines 724 of the coupler body 704 are receivedin the corresponding slots 734 and confront the splines 736 of the shaft722. When the door 24 is opened, the door 24 is pivoted about the axis86 as indicated by arrow 776 in FIG. 20. As the door 24 is pivoted, thesplines 142 of the coupler body 704 apply a load to the slots 90 of thehinge pin 68 in the direction indicated by arrow 780 in FIG. 20.Likewise the splines 724 of the coupler body 704 apply a load to theslots 734 and the splines 736 of the shaft 722 in the directionindicated by arrow 782.

The load is transferred through the coupler body 704 to the hingebracket 40 via the hinge pin 68. The engagement between the surfaces128, 138 of the coupler body 704 and the surfaces 90, 92, respectively,of the hinge pin 68 prevents the coupler body 572 from pivoting with thedoor 24. Likewise, the engagement between the splines 724, 736 of thecoupler body 572 and the shaft 722 prevents the shaft 722 from pivotingwith the door.

When sufficient force is applied to the door 24, the bias exerted by thespring 756 of the closer assembly 702 is overcome and the door 24 ispivoted about the axis 86. When the door 24 is released at an openposition, the spring 756 urges the door to return to the closedposition.

While the disclosure has been illustrated and described in detail in thedrawings and foregoing description, such an illustration and descriptionis to be considered as exemplary and not restrictive in character, itbeing understood that only illustrative embodiments have been shown anddescribed and that all changes and modifications that come within thespirit of the disclosure are desired to be protected.

For example, in other embodiments, the left-hand door may have anadjustable hinge assembly operable to raise and lower the left-hand doorrelative to the cabinet. Similarly, the right-hand door may have a fixedhinge assembly that does not permit the right-hand door to be raised andlowered when the door is in the closed position.

There are a plurality of advantages of the present disclosure arisingfrom the various features of the method, apparatus, and system describedherein. It will be noted that alternative embodiments of the method,apparatus, and system of the present disclosure may not include all ofthe features described yet still benefit from at least some of theadvantages of such features. Those of ordinary skill in the art mayreadily devise their own implementations of the method, apparatus, andsystem that incorporate one or more of the features of the presentinvention and fall within the spirit and scope of the present disclosureas defined by the appended claims.

1. A domestic refrigerator comprising: a cabinet having atemperature-controlled compartment defined therein, a door positioned ata front of the cabinet, the door being operable to pivot about an axisof rotation between (i) a closed position in which user access to thetemperature-controlled compartment is limited and (ii) an open positionin which user access to the temperature-controlled compartment ispermitted, a closer assembly including a base secured to the door and adownwardly-extending shaft moveably coupled to the base, a mountingbracket coupled to the front of the cabinet, a hinge pin defining theaxis of rotation and extending upwardly from the mounting bracket, and acoupler body having (i) a first inner sidewall defining a lower aperturethat receives an upper end of the hinge pin, and (ii) a second innersidewall defining an upper aperture that receives a lower end of theshaft, wherein (i) the shaft of the closer assembly has a firstplurality of splines formed thereon, and (ii) the second inner sidewallof the coupler body has a second plurality of splines formed thereon,the second plurality of splines engaging the first plurality of splinesto prevent relative axial rotation between the coupler body and theshaft.
 2. The domestic refrigerator of claim 1, wherein: the couplerbody has a third plurality of splines that extend inwardly from thefirst inner sidewall, the hinge pin includes (i) a shaft having an upperend positioned in the lower aperture of the coupler body, and (ii) aplurality of longitudinal slots defined in the shaft, and each spline ofthe third plurality of splines is received in a correspondinglongitudinal slot of the hinge pin to prevent rotation of the couplerbody about the axis of rotation.
 3. The domestic refrigerator of claim1, further comprising an adjustment mechanism configured to move thedoor vertically relative to the cabinet between a first position and asecond position.
 4. The domestic refrigerator of claim 3, wherein: thehinge pin has a passageway defined therein, and the adjustment mechanismincludes a threaded rod positioned in the passageway of the shaft, thethreaded rod having an upper end engaged with the coupler body.
 5. Thedomestic refrigerator of claim 4, wherein the coupler body includes acentral shaft positioned in the lower aperture, the central shaft havinga lower end that is (i) positioned in the passageway of the shaft and(ii) engaged with the upper end of the threaded rod.
 6. The domesticrefrigerator of claim 4, wherein: the threaded rod has a plurality ofouter threads, and the hinge pin includes an inner wall that defines thepassageway therethrough, the inner wall of the hinge pin having aplurality of inner threads defined therein that are engaged with theouter threads of the threaded rod such that (i) rotation of the threadedrod in a first direction causes upward movement of the coupler body andthe door, and (ii) rotation of the threaded rod in a second directioncauses downward movement of the coupler body and the door.
 7. Thedomestic refrigerator of claim 6, wherein the adjustment mechanismincludes a stop configured to prevent upward movement of the threadedrod beyond a predetermined position corresponding to the second positionof the door.
 8. The domestic refrigerator of claim 7, wherein the stopincludes a substantially smooth section of the inner wall of the hingepin, the substantially smooth section being positioned above theplurality of inner threads.
 9. The domestic refrigerator of claim 1,wherein the closer assembly includes a biasing element having a firstend coupled to the shaft and a second end coupled to the base, thebiasing element being configured to inhibit movement of the door aboutthe axis of rotation.
 10. The domestic refrigerator of claim 1, whereinthe first plurality of splines include six splines.
 11. A domesticrefrigerator comprising: a cabinet having a temperature-controlledcompartment defined therein, a door operable to pivot about an axis ofrotation to an open position in which user access to thetemperature-controlled compartment is permitted, a closer assemblyincluding a base secured to the door and a downwardly-extending shaftmoveably coupled to the base, and a hinge assembly including a hinge pindefining the axis of rotation and an adjustment mechanism configured tomove the door vertically between a first position and a second position,the adjustment mechanism including: a coupler body positioned over thehinge pin, the coupler body including an inner side wall that definesaperture receiving the shaft of the closer assembly, a threaded rodpositioned in a passageway defined in the hinge pin, the threaded rodbeing configured to rotate in (i) a first direction to cause upwardmovement of the door and (ii) a second direction to cause downwardmovement of the door, and a stop positioned in the passageway defined inthe hinge pin, the stop being configured to prevent upward movement ofthe threaded rod beyond a predetermined position corresponding to thesecond position of the door.
 12. The domestic refrigerator of claim 11,wherein the coupler body includes a central shaft having a lower endthat is (i) positioned in the passageway of the hinge pin and (ii)engaged with an upper end of the threaded rod.
 13. The domesticrefrigerator of claim 11, wherein the hinge pin includes a longitudinalslot defined in an outer surface thereof, and the coupler body includesa spline extending from an inner wall thereof, the spline being receivedin the longitudinal slot of the hinge pin.
 14. The domestic refrigeratorof claim 13, wherein (i) the shaft of the closer assembly has a splineformed thereon, and (ii) the coupler body has a second spline formedthereon, the spline of the shaft engaging the second spline of thecoupler body to prevent relative axial rotation between the coupler bodyand the shaft.
 15. The domestic refrigerator of claim 14, wherein thecloser assembly includes a biasing element having a first end coupled tothe shaft and a second end coupled to the base, the biasing elementbeing configured to inhibit movement of the door about the axis ofrotation.
 16. The domestic refrigerator of claim 15, wherein the biasingelement includes a coil spring.
 17. The domestic refrigerator of claim14, wherein the shaft of the closer assembly includes an upper surfacehaving the spline formed thereon and a lower surface that issubstantially smooth.
 18. The domestic refrigerator of claim 13, whereinthe longitudinal slot includes at least six longitudinal slots, and thespline includes at least six splines extending from the inner wall ofthe coupler body, each of the splines being received in a correspondinglongitudinal slot of the hinge pin.
 19. A domestic appliance comprising:a cabinet, a door positioned at a front of the cabinet, a closerassembly secured to the door, the closer assembly including adownwardly-extending shaft, a mounting bracket coupled to the front ofthe cabinet, a hinge pin extending upwardly from the mounting bracket,and a coupler body having (i) a first inner sidewall defining a loweraperture that receives an upper end of the hinge pin, and (ii) a secondinner sidewall defining an upper aperture that receives a lower end ofthe shaft, wherein (i) the shaft of the closer assembly has a firstplurality of splines formed thereon, and (ii) the second inner sidewallhas a second plurality of splines formed thereon, the second pluralityof splines engaging the first plurality of splines.
 20. The domesticappliance of claim 19, wherein: the hinge pin includes (i) a shafthaving an upper end positioned in the lower aperture of the couplerbody, and (ii) a plurality of longitudinal slots defined in the shaft,and the coupler body has a third plurality of splines that extendinwardly from an inner wall, each spline of the third plurality ofsplines being received in a corresponding longitudinal slot of the hingepin.